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离体兔回肠中的离子转运。II. 主动钠转运与主动糖转运之间的相互作用。

ION TRANSPORT IN ISOLATED RABBIT ILEUM. II. THE INTERACTION BETWEEN ACTIVE SODIUM AND ACTIVE SUGAR TRANSPORT.

作者信息

SCHULTZ S G, ZALUSKY R

出版信息

J Gen Physiol. 1964 Jul;47(6):1043-59. doi: 10.1085/jgp.47.6.1043.

DOI:10.1085/jgp.47.6.1043
PMID:14192544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2195378/
Abstract

The addition of actively transported sugars to the solution bathing the mucosal surface of an in vitro preparation of distal rabbit ileum results in a rapid increase in the transmural potential difference, the short-circuit current, and the rate of active Na transport from mucosa to serosa. These effects are dependent upon the active transport of the sugar per se and are independent of the metabolic fate of the transported sugar. Furthermore, they are inhibited both by low concentrations of phlorizin in the mucosal solution and by low concentrations of ouabain in the serosal solution. The increase in the short-circuit current, DeltaI(sc), requires the presence of Na in the perfusion medium and its magnitude is a linear function of the Na concentration. On the other hand, DeltaI(sc) is a saturable function of the mucosal sugar concentration which is consistent with Michaelis-Menten kinetics suggesting that the increase in active Na transport is stoichiometrically related to the rate of active sugar transport. An interpretation of these findings in terms of a hypothetical model for intestinal Na and sugar transport is presented.

摘要

向体外制备的兔远端回肠黏膜表面浸泡的溶液中添加主动转运的糖类,会导致跨壁电位差、短路电流以及从黏膜到浆膜的主动钠转运速率迅速增加。这些效应取决于糖类本身的主动转运,与被转运糖类的代谢命运无关。此外,它们会受到黏膜溶液中低浓度根皮苷以及浆膜溶液中低浓度哇巴因的抑制。短路电流的增加量ΔI(sc)需要灌注介质中有钠的存在,其大小是钠浓度的线性函数。另一方面,ΔI(sc)是黏膜糖类浓度的饱和函数,这与米氏动力学一致,表明主动钠转运的增加与主动糖类转运速率在化学计量上相关。本文根据一个关于肠道钠和糖类转运的假设模型对这些发现进行了解释。

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